Combining scattering experiments and colloid theory to characterize charge effects in concentrated antibody solutions

TL;DR

This study combines experimental techniques and colloid theory to analyze charge effects in concentrated antibody solutions, revealing insights into their structural and dynamic properties relevant for stability and formulation.

Contribution

It introduces a systematic approach integrating experiments and simulations to better understand charge interactions in monoclonal antibody solutions.

Findings

Charge influences antibody solution properties significantly.

Colloid models can describe antibody interactions with limitations.

Shape and charge anisotropy are crucial at high concentrations.

Abstract

Charges and their contribution to protein-protein interactions are essential for the key structural and dynamic properties of monoclonal antibody (mAb) solutions. In fact, they influence the apparent molecular weight, the static structure factor, the collective diffusion coefficient or the relative viscosity and their concentration dependence. Further, charges play an important role in the colloidal stability of mAbs. There exist standard experimental tools to characterise mAb net charges such as the measurement of the electrophoretic mobility, the second virial coefficient, or the diffusion interaction parameter. However, the resulting values are difficult to be directly related to the actual overall net charge of the antibody and to theoretical predictions based on its known molecular structure. Here, we report the results of a systematic investigation of the solution properties of a charged IgG1 mAb as a function of concentration and ionic strength using a combination of electrophoretic measurements, static and dynamic light scattering, small-angle x-ray scattering (SAXS), and tracer particle-based microrheology. We analyse and interpret the experimental results using established colloid theory and coarse-grained computer simulations. We discuss the potential and limits of colloidal models for the description of interaction effects of charged mAbs, in particular pointing out the importance of incorporating shape and charge anisotropy when attempting to predict structural and dynamic solution properties at high concentrations.